/**************************************************************************//**
 * @file     main.c
 * @version  V3.00
 * $Revision: 18 $
 * $Date: 16/06/21 7:43p $
 * @brief
 *           Demonstrate how a Master uses I2C address 0x0 to write data to I2C Slave.
 *           Needs to work with I2C_GCMode_Slave sample code.
 * @note
 * Copyright (C) 2014~2015 Nuvoton Technology Corp. All rights reserved.
 *
 ******************************************************************************/
#include <stdio.h>
#include "NUC123.h"

#define PLLCON_SETTING      CLK_PLLCON_72MHz_HXT
#define PLL_CLOCK           72000000

/*---------------------------------------------------------------------------------------------------------*/
/* Global variables                                                                                        */
/*---------------------------------------------------------------------------------------------------------*/
volatile uint8_t g_u8DeviceAddr;
volatile uint8_t g_au8MstTxData[3];
volatile uint8_t g_u8MstDataLen;
volatile uint8_t g_u8MstEndFlag = 0;

typedef void (*I2C_FUNC)(uint32_t u32Status);

static I2C_FUNC s_I2C0HandlerFn = NULL;

/*---------------------------------------------------------------------------------------------------------*/
/*  I2C0 IRQ Handler                                                                                       */
/*---------------------------------------------------------------------------------------------------------*/
void I2C0_IRQHandler(void)
{
    uint32_t u32Status;

    u32Status = I2C_GET_STATUS(I2C0);

    if(I2C_GET_TIMEOUT_FLAG(I2C0))
    {
        /* Clear I2C0 Timeout Flag */
        I2C_ClearTimeoutFlag(I2C0);
    }
    else
    {
        if(s_I2C0HandlerFn != NULL)
            s_I2C0HandlerFn(u32Status);
    }
}

/*---------------------------------------------------------------------------------------------------------*/
/*  I2C Tx Callback Function                                                                               */
/*---------------------------------------------------------------------------------------------------------*/
void I2C_MasterTx(uint32_t u32Status)
{
    if(u32Status == 0x08)                       /* START has been transmitted */
    {
        I2C_SET_DATA(I2C0, g_u8DeviceAddr << 1);    /* Write SLA+W to Register I2CDAT */
        I2C_SET_CONTROL_REG(I2C0, I2C_I2CON_SI);
    }
    else if(u32Status == 0x18)                  /* SLA+W has been transmitted and ACK has been received */
    {
        I2C_SET_DATA(I2C0, g_au8MstTxData[g_u8MstDataLen++]);
        I2C_SET_CONTROL_REG(I2C0, I2C_I2CON_SI);
    }
    else if(u32Status == 0x20)                  /* SLA+W has been transmitted and NACK has been received */
    {
        I2C_SET_CONTROL_REG(I2C0, I2C_I2CON_STA_STO_SI);
    }
    else if(u32Status == 0x28)                  /* DATA has been transmitted and ACK has been received */
    {
        if(g_u8MstDataLen != 3)
        {
            I2C_SET_DATA(I2C0, g_au8MstTxData[g_u8MstDataLen++]);
            I2C_SET_CONTROL_REG(I2C0, I2C_I2CON_SI);
        }
        else
        {
            I2C_SET_CONTROL_REG(I2C0, I2C_I2CON_STO_SI);
            g_u8MstEndFlag = 1;
        }
    }
    else
    {
        /* TO DO */
        printf("Status 0x%x is NOT processed\n", u32Status);
    }
}

void SYS_Init(void)
{
    /*---------------------------------------------------------------------------------------------------------*/
    /* Init System Clock                                                                                       */
    /*---------------------------------------------------------------------------------------------------------*/

    /* Enable XT1_OUT (PF0) and XT1_IN (PF1) */
    SYS->GPF_MFP &= ~(SYS_GPF_MFP_PF0_Msk | SYS_GPF_MFP_PF1_Msk);
    SYS->GPF_MFP |= SYS_GPF_MFP_PF0_XT1_OUT | SYS_GPF_MFP_PF1_XT1_IN;

    /* Enable Internal RC 22.1184MHz clock */
    CLK_EnableXtalRC(CLK_PWRCON_OSC22M_EN_Msk);

    /* Waiting for Internal RC clock ready */
    CLK_WaitClockReady(CLK_CLKSTATUS_OSC22M_STB_Msk);

    /* Switch HCLK clock source to Internal RC and HCLK source divide 1 */
    CLK_SetHCLK(CLK_CLKSEL0_HCLK_S_HIRC, CLK_CLKDIV_HCLK(1));

    /* Enable external XTAL 12MHz clock */
    CLK_EnableXtalRC(CLK_PWRCON_XTL12M_EN_Msk);

    /* Waiting for external XTAL clock ready */
    CLK_WaitClockReady(CLK_CLKSTATUS_XTL12M_STB_Msk);

    /* Set core clock as PLL_CLOCK from PLL */
    CLK_SetCoreClock(PLL_CLOCK);

    /* Enable UART module clock */
    CLK_EnableModuleClock(UART0_MODULE);

    /* Enable I2C0 module clock */
    CLK_EnableModuleClock(I2C0_MODULE);

    /* Select UART module clock source */
    CLK_SetModuleClock(UART0_MODULE, CLK_CLKSEL1_UART_S_HXT, CLK_CLKDIV_UART(1));

    /*---------------------------------------------------------------------------------------------------------*/
    /* Init I/O Multi-function                                                                                 */
    /*---------------------------------------------------------------------------------------------------------*/

    /* Set GPB multi-function pins for UART0 RXD and TXD */
    SYS->GPB_MFP &= ~(SYS_GPB_MFP_PB0_Msk | SYS_GPB_MFP_PB1_Msk);
    SYS->GPB_MFP |= (SYS_GPB_MFP_PB0_UART0_RXD | SYS_GPB_MFP_PB1_UART0_TXD);

    /* Set GPF multi-function pins for I2C0 SDA and SCL */
    SYS->GPF_MFP &= ~(SYS_GPF_MFP_PF2_Msk | SYS_GPF_MFP_PF3_Msk);
    SYS->GPF_MFP |= (SYS_GPF_MFP_PF2_I2C0_SDA | SYS_GPF_MFP_PF3_I2C0_SCL);
    SYS->ALT_MFP1 &= ~(SYS_ALT_MFP1_PF2_Msk | SYS_ALT_MFP1_PF3_Msk);
    SYS->ALT_MFP1 |= (SYS_ALT_MFP1_PF2_I2C0_SDA | SYS_ALT_MFP1_PF3_I2C0_SCL);
}

void UART0_Init()
{
    /*---------------------------------------------------------------------------------------------------------*/
    /* Init UART                                                                                               */
    /*---------------------------------------------------------------------------------------------------------*/
    /* Reset IP */
    SYS_ResetModule(UART0_RST);

    /* Configure UART0 and set UART0 Baudrate */
    UART_Open(UART0, 115200);
}

void I2C0_Init(void)
{
    /* Open I2C module and set bus clock */
    I2C_Open(I2C0, 100000);

    /* Get I2C0 Bus Clock */
    printf("I2C clock %d Hz\n", I2C_GetBusClockFreq(I2C0));

    /* Set I2C 4 Slave Addresses */
    I2C_SetSlaveAddr(I2C0, 0, 0x15, 0);   /* Slave Address : 0x15 */
    I2C_SetSlaveAddr(I2C0, 1, 0x35, 0);   /* Slave Address : 0x35 */
    I2C_SetSlaveAddr(I2C0, 2, 0x55, 0);   /* Slave Address : 0x55 */
    I2C_SetSlaveAddr(I2C0, 3, 0x75, 0);   /* Slave Address : 0x75 */

    /* Enable I2C interrupt */
    I2C_EnableInt(I2C0);
    NVIC_EnableIRQ(I2C0_IRQn);
}

void I2C0_Close(void)
{
    /* Disable I2C0 interrupt and clear corresponding NVIC bit */
    I2C_DisableInt(I2C0);
    NVIC_DisableIRQ(I2C0_IRQn);

    /* Disable I2C0 and close I2C0 clock */
    I2C_Close(I2C0);
    CLK_DisableModuleClock(I2C0_MODULE);

}


/*---------------------------------------------------------------------------------------------------------*/
/*  Main Function                                                                                          */
/*---------------------------------------------------------------------------------------------------------*/
int32_t main(void)
{
    uint32_t i;

    /* Unlock protected registers */
    SYS_UnlockReg();

    /* Init System, IP clock and multi-function I/O */
    SYS_Init();

    /* Init UART0 for printf */
    UART0_Init();

    /* Lock protected registers */
    SYS_LockReg();

    /*
        This sample code sets I2C bus clock to 100kHz. Then, accesses Slave (GC Mode) with Byte Write
        and Byte Read operations, and check if the read data is equal to the programmed data.
    */
    printf("\n");
    printf("+-------------------------------------------------------------+\n");
    printf("| I2C Driver Sample Code (Master) for access Slave (GC Mode)  |\n");
    printf("| Needs to work with I2C_GCMode_Slave sample code             |\n");
    printf("|     I2C Master (I2C0) <---> I2C Slave(I2C0)(Address: 0x00)  |\n");
    printf("| !! This sample code requires two borads to test !!          |\n");
    printf("+-------------------------------------------------------------+\n");

    printf("Configure I2C0 as a master.\n");
    printf("The I/O connection for I2C0:\n");
    printf("I2C0_SDA(PF.2), I2C0_SCL(PF.3)\n");

    /* Init I2C0 to access EEPROM */
    I2C0_Init();

    printf("\n");

    /* Send Slave GC Mode address */
    g_u8DeviceAddr = 0x00;

    printf("Check I2C Slave(I2C0) is running first!\n");
    printf("Press any key to continue.\n");
    getchar();
    for(i = 0; i < 0x100; i++)
    {
        g_au8MstTxData[0] = (uint8_t)((i & 0xFF00) >> 8);
        g_au8MstTxData[1] = (uint8_t)(i & 0x00FF);
        g_au8MstTxData[2] = (uint8_t)(g_au8MstTxData[1] + 3);

        g_u8MstDataLen = 0;
        g_u8MstEndFlag = 0;

        /* I2C function to write data to slave */
        s_I2C0HandlerFn = (I2C_FUNC)I2C_MasterTx;

        /* I2C as master sends START signal */
        I2C_SET_CONTROL_REG(I2C0, I2C_I2CON_STA);

        /* Wait I2C Tx Finish */
        while(g_u8MstEndFlag == 0);
    }
    printf("Master Access Slave(0x%X) at GC Mode Test OK\n", g_u8DeviceAddr);

    s_I2C0HandlerFn = NULL;

    /* Close I2C0 */
    I2C0_Close();

    while(1);
}



